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[1]郭远哲,毛思颖,罗晓刚*.原位制备ZIF-8/纤维素微球及其控制释放5-氟尿嘧啶的研究[J].武汉工程大学学报,2024,46(02):137-147.[doi:10.19843/j.cnki.CN42-1779/TQ.202303020]
 GUO Yuanzhe,MAO Siying,LUO Xiaogang*.ZIF-8/cellulose microspheres prepared in situ tocontrol release of 5-fluorouracil[J].Journal of Wuhan Institute of Technology,2024,46(02):137-147.[doi:10.19843/j.cnki.CN42-1779/TQ.202303020]
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原位制备ZIF-8/纤维素微球
及其控制释放5-氟尿嘧啶的研究
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《武汉工程大学学报》[ISSN:1674-2869/CN:42-1779/TQ]

卷:
46
期数:
2024年02期
页码:
137-147
栏目:
材料科学与工程
出版日期:
2024-04-28

文章信息/Info

Title:
ZIF-8/cellulose microspheres prepared in situ to
control release of 5-fluorouracil
文章编号:
1674 - 2869(2024)02 - 0137- 11
作者:
郭远哲1毛思颖1罗晓刚*12
1. 武汉工程大学化工与制药学院,绿色化工过程教育部重点实验室(武汉工程大学),湖北 武汉 430205;
2. 湖北三峡实验室,湖北 宜昌 443007
Author(s):
GUO Yuanzhe1MAO Siying1LUO Xiaogang*12
1. School of Chemical Engineering and Pharmacy,Wuhan Institute of Technology;Key Laboratory of Green Chemical Process of Ministry of Education(Wuhan Institute of Technology),Wuhan 430205,China;
2. Hubei Three Gorges Laboratory,Yichang 443007,China
关键词:
纤维素微球ZIF-85-氟尿嘧啶控制释放
Keywords:
cellulose microspheres ZIF-8 5-fluorouracil controlled release
分类号:
X703
DOI:
10.19843/j.cnki.CN42-1779/TQ.202303020
文献标志码:
A
摘要:
在纤维素微球(CM)上设计了沸石型咪唑骨架材料8/纤维素复合微球(ZIF-8@CM)作为5-氟尿嘧啶(5-FU)的载体并对5-FU进行控制释放。以CM、硝酸锌和2-甲基咪唑为原料,采用原位法制备了ZIF-8@CM。通过氢键、静电相互作用和π-π堆积作用将5-FU加载到ZIF-8@CM上。利用扫描电子显微术、能量色散X射线分析法、傅里叶变换红外光谱法、X射线衍射、X射线光电子能谱法和热重分析对样品进行表征,结果表明成功制备了ZIF-8@CM,并在ZIF-8@CM上成功加载了5-FU。ZIF-8@CM对5-FU的负载量可达74.10 mg·g-1,远高于CM(2.84 mg·g-1)。此外,ZIF-8@CM-5-FU可在pH=5.0的磷酸缓冲溶液(PBS)环境下持续释放5-FU 600 min,释放量达到63.4%,但在pH=7.4的PBS环境下仅释放37.6%。5-FU的释放遵循一级动力学和Fickian扩散机制。在细胞实验中已证实ZIF-8@CM具有良好的生物相容性和极低的细胞毒性,是5-FU安全释放的合适载体。本研究为设计一种5-FU的新型载体提供了思路。

Abstract:
Zeolitic imidazole framework 8/cellulose composite microsphere(ZIF-8@CM) was designed on the cellulose microsphere(CM) as the carrier of 5-fluorouracil(5-FU) to control the release of 5-FU. ZIF-8@CM was prepared by an in-situ method from CM,zinc nitrate and 2-methylimidazole. 5-FU was loaded on ZIF-8@CM by hydrogen bonding, electrostatic interaction and π-π stacking. The samples were characterized by scanning electron microscopy, energy-dispersion X-ray analysis, Fourier transform infrared spectroscopy, X-ray diffraction, X-ray photoelectron spectroscopy and thermogravimetric analysis. The results show that ZIF-8@CM is successfully prepared and 5-FU is loaded on ZIF-8@CM. The loading capacity of 5-FU can reach 74.10 mg·g-1,much higher than that of CM (2.84 mg·g-1). In addition,ZIF-8@CM-5-FU can release 63.4% of 5-FU over 600 min in phosphoric acid buffer solution (PBS) at pH=5.0,but only 37.6% in PBS at pH=7.4. The release of 5-FU follows first-order kinetics and Fickian diffusion mechanism. Cell experiments prove that ZIF-8@CM have good biocompatibility and very low cytotoxicity,and ZIF-8@CM-5-FU is a suitable vector for safe release of 5-FU. This study provides an idea for designing a new type of 5-FU carrier.

参考文献/References:

[1] LONGLEY D B, HARKIN D P, JOHNSTON P G. 5-fluorouracil:mechanisms of action and clinical strategies [J]. Nature Reviews Cancer,2003,3(5):330-338.

[2] SUN X X,LIU C,OMER A M,et al. pH-sensitive ZnO/carboxymethyl cellulose/chitosan bio-nanocomposite beads for colon-specific release of 5-fluorouracil [J]. International Journal of Biological Macromolecules,2019,128:468-479.
[3] ENTEZAR-ALMAHDI E, MOHAMMADI-SAMANI S,TAYEBI L,et al. Recent advances in designing 5-fluorouracil delivery systems:a stepping stone in the safe treatment of colorectal cancer [J]. International Journal of Nanomedicine,2020,15:5445-5458.
[4] LIU G, FRANSSEN E, FITCH M I, et al. Patient preferences for oral versus intravenous palliative chemotherapy [J]. Journal of Clinical Oncology,1997,15(1):110-115.
[5] JIVRAJ M, MARTINI L G, THOMSON C M. An overview of the different excipients useful for the direct compression of tablets [J]. Pharmaceutical Science & Technology Today,2000,3(2):58-63.
[6] SHEIKHI A, HAYASHI J, EICHENBAUM J, et al. Recent advances in nanoengineering cellulose for cargo delivery [J]. Journal of Control Release,2019,294:53-76.
[7] RAMESH BABU V,SAIRAM M,HOSAMANI K M,et al. Preparation of sodium alginate-methylcellulose blend microspheres for controlled release of nifedipine [J]. Carbohydrate Polymers,2007,69(2):241-250.
[8] LUO X G, LIU L M, WANG L R, et al. Facile synthesis and low concentration tylosin adsorption performance of chitosan/cellulose nanocomposite microspheres [J]. Carbohydrate Polymers,2019,206:633-640.
[9] LUO X G, LIU S L, ZHOU J P,et al. In situ synthesis of Fe3O4/cellulose microspheres with magnetic-induced protein delivery [J]. Journal of Materials Chemistry,2009,19(21):3538-3545.
[10] KAMALY N,YAMEEN B,WU J,et al. Degradable controlled-release polymers and polymeric nanoparticles:mechanisms of controlling drug release [J]. Chemical Reviews,2016,116(4):2602-2663.
[11] WU S M,GONG Y Q,LIU S L,et al. Functionalized phosphorylated cellulose microspheres:design,characterization and ciprofloxacin loading and releasing properties [J]. Carbohydrate Polymers,2021,254:117421.
[12] LEE H,CHI W S,LEE M J,et al. Network-nanostructured ZIF-8 to enable percolation for enhanced gas transport [J]. Advanced Functional Materials,2022,32(47):2207775.
[13] DORNELES de MELLO M,AHMAD M,LEE D T,et al. In situ tracking of nonthermal plasma etching of ZIF-8 films [J]. ACS Applied Materials & Interfaces,2022,14(16):19023-19030.
[14] WANG Q X, LEI Y T, CUI Y Y, et al. Thermal stability and kinetics of single I2@ZIF-8 particles [J]. ACS Applied Materials & Interfaces,2022,14(19):22643-22649.
[15] LIAN H Q,BAO B,CHEN J F,at al. Controllable synthesis of ZIF-8 interlocked membranes for propylene/propane separation [J]. Separation and Purification Technology,2022,300:121811.
[16] REN L P, YU Y, YANG Y,et al. Efficient removal of formaldehyde with ZIF-8 growth on TIO2-coated activated carbon fiber felts prepared via atomic layer deposition [J]. Journal of Materials Science,2020,55(8):3167-3180.
[17] WANG Y,YAN J H,WEN N C,et al. Metal-organic frameworks for stimuli-responsive drug delivery [J]. Biomaterials,2020,230:119619.
[18] SIMAGINA A A,POLYNSKI M V,VINOGRADOV A V,et al. Towards rational design of metal-organic framework-based drug delivery systems [J]. Russian Chemical Reviews,2018,87(9):831-858.
[19] CAI J,LIU Y T,ZHANG L N. Dilute solution properties of cellulose in LiOH/urea aqueous system [J]. Journal of Polymer Science: Part B:Polymer Physics,2006,44(21):3093-3101.
[20] LUO X G,YUAN J, LIU Y G, et al. Improved solid-phase synthesis of phosphorylated cellulose microsphere adsorbents for?highly effective Pb2+ removal from water:batch and fixed-bed column performance and adsorption mechanism [J]. ACS Sustainable Chemistry & Engineering,2017,5(6):5108-5117.
[21] EBRAHIMI R, SALAVATY M. Controlled drug delivery of ciprofloxacin from ultrasonic hydrogel [J]. e-Polymers,2018,18(2):187-195.
[22] GHOSH S K, DAS A, BASU A, et al. Semi-interpenetrating hydrogels from carboxymethyl guar gum and gelatin for ciprofloxacin sustained release [J]. International Journal of Biological Macromolecules,2018,120:1823-1833.
[23] SHARKAWY A,FERNANDES I P,BARREIRO M F,et al. Aroma-loaded microcapsules with antibacterial activity for eco-friendly textile application:synthesis,characterization,release,and green grafting[J]. Industrial & Engineering Chemistry Research,2017,56(19):5516-5526.
[24] SILVA M, MARTINS I M, BARREIRO M F, et al. Functionalized textiles with PUU/limonene microcapsules:effect of finishing methods on fragrance release [J]. The Journal of the Textile Institute,2017,108(3):361-367.
[25] LI J, XIN M X, HUO Y H, et al. Synthesis of β-cyclodextrin-PEG-G molecules to delay tumor growth and application of β-cyclodextrin-PEG-G aggregates as drug carrier[J]. Carbohydrate Polymers,2020,229:115478.
[26] ZHANG H, LUO X G, TANG H, et al. A novel candidate for wound dressing:transparent porous maghemite/cellulose nanocomposite membranes with controlled release of doxorubicin from a simple approach [J]. Materials Science and Engineering: C,2017,79:84-92.
[27] JIAN M P, LIU B, ZHANG G S, et al. Adsorptive removal of arsenic from aqueous solution by zeolitic imidazolate framework-8 (ZIF-8) nanoparticles [J]. Colloids and Surfaces A:Physicochemical and Engineering Aspects,2015,465:67-76.
[28] GROSS A F,SHERMAN E,VAJO J J. Aqueous room temperature synthesis of cobalt and zinc sodalite zeolitic imidizolate frameworks [J]. Dalton Transactions,2012,41(18):5458-5460.
[29] JIA M M, ZHANG X F, FENG Y, et al. In-situ growing ZIF-8 on cellulose nanofibers to form gas separation membrane for CO2 separation [J]. Journal of Membrane Science,2020,595:117579.
[30] LIU B,JIAN M P,LIU R P,et al. Highly efficient removal of arsenic(Ш) from aqueous solution by zeolitic imidazolate frameworks with different morphology [J]. Colloids and Surfaces A:Physicochemical and Engineering Aspects,2015,481:358-366.
[31] NABIPOUR H,SADR M H,BARDAJEE G R. Synthesis and characterization of nanoscale zeolitic imidazolate frameworks with ciprofloxacin and their applications as antimicrobial agents [J]. New Journal of Chemistry,2017,41(15):7364-7370.
[32] JAVANBAKHT S,HEMMATI A,NAMAZI H,et al. Carboxymethylcellulose-coated 5-fluorouracil@MOF-5 nano-hybrid as a bio-nanocomposite carrier for the anticancer oral delivery [J]. International Journal of Biological Macromolecules,2020,155:876-882.
[33] YU L,CHEN H X,YUE J,et al. Metal-organic framework enhances aggregation-induced fluorescence of chlortetracycline and the application for detection [J]. Analytical Chemistry,2019,91(9):5913-5921.
[34] GONG X Y,WANG Y X,CHEN L Y. Enhanced emulsifying properties of wood-based cellulose nanocrystals as Pickering emulsion stabilizer [J]. Carbohydrate Polymers,2017,169:295-303.
[35] ZHAI X C,LIN D H,LI W W,et al. Improved characterization of nanofibers from bacterial cellulose and its potential application in fresh-cut apples [J]. International Journal of Biological Macromolecules,2020,149:178-186.
[36] COUDERT F X.Molecular mechanism of swing effect in zeolitic imidazolate framework ZIF-8:continuous deformation upon adsorption [J]. ChemPhysChem,2017,18(19):2732-2738.
[37] 沈浩,黄茜,冯锐捷,等. Zr掺杂介孔硅对亚甲基蓝的选择性吸附性能[J]. 武汉工程大学学报,2023,45(1):25-34.
[38] LUO X G, CAI Y X, LIU L M, et al. Cr(VI) adsorption performance and mechanism of an effective activated carbon prepared from bagasse with a one-step pyrolysis and ZnCl2 activation method [J]. Cellulose,2019,26(8):4921-4934.
[39] YANG C, WANG L R,YU Y Q,et al. Highly efficient removal of amoxicillin from water by Mg-Al layered double hydroxide/cellulose nanocomposite beads synthesized through in-situ coprecipitation method [J]. International Journal of Biological Macromolecules,2020,149:93-100.
[40] ADHIKARI C,DAS A,CHAKRABORTY A. Zeolitic imidazole framework (ZIF) nanospheres for easy encapsulation and controlled release of an anticancer drug doxorubicin under different external stimuli:a way toward smart drug delivery system [J]. Molecular Pharmaceutics,2015,12(9):3158-3166.
[41] LI C,LIU X Y,ZHANG Y L,et al. Nanochaperones mediated delivery of insulin [J]. Nano Letters,2020,20(3):1755-1765.
[42] AGGRAWAL S,CHAUHAN I,MOHANTY P. Immobilization of Bi2O3 nanoparticles on the cellulose fibers of paper matrices and investigation of its antibacterial activity against E. coli in visible light [J]. Materials Express,2015,5(5):429-436.
[43] CHAUHAN I, MOHANTY P. Immobilization of titania nanoparticles on the surface of cellulose fibres by a facile single step hydrothermal method and study of their photocatalytic and antibacterial activities [J]. RSC Advances,2014,4(101):57885-57890.
[44] SU Z P,ZHANG M Y,LU Z Q,et al. Functionalization of cellulose fiber by in situ growth of zeolitic imidazolate framework-8 (ZIF-8) nanocrystals for preparing a cellulose-based air filter with gas adsorption ability [J]. Cellulose,2018,25(3):1997-2008.

相似文献/References:

备注/Memo

备注/Memo:
收稿日期:2023-03-14
基金项目:国家自然科学基金(51773159)
作者简介:郭远哲,硕士研究生。Email:[email protected]
*通信作者:罗晓刚,博士,教授。Email:[email protected]
引文格式:郭远哲,毛思颖,罗晓刚. 原位制备ZIF-8/纤维素微球及其控制释放5-氟尿嘧啶的研究[J]. 武汉工程大学学报,2024,46(2):137-147.
更新日期/Last Update: 2024-05-01